Flashes of brilliance in the brain – the best neuroscience images of 2013

Pretty pictures and popular neuroscience go hand-in-hand. People love to see the contours of their brain on an MRI and journalists are drawn to a brain flashing away with activity. There have been some fantastic images from neuroscience in 2013. Here are my favourites, one for each month starting way back in January 2013.

Disclaimer – We own no rights to any of the images on this page. All images are credited to the original authors and copyright holders. The MRC’s Biomedical Picture of the Day has been used as inspiration for some of the images.

January – New eyes for blindness

Blindness is a major challenge to the neuroscience field. Untreatable blindness is often caused by a degeneration of the light-sensitive cells of the retina. Here, researchers from University College London, UK have injected new photoreceptor cells into the retina of mice with retinal degeneration restoring normal responses to light!

Host retina cells are shown in blue, injected new photoreceptive cells are shown in green. The top left is a healthy mouse. The next three images show three different types of genetic blindness models in mice – all show integration of the injected cells. From Barber et al. PNAS 110(1): 354-359
Host retina cells are shown in blue, injected new photoreceptive cells are shown in green. The top left is a healthy mouse. The next three images show three different types of genetic blindness models in mice – all show integration of the injected cells. From Barber et al. PNAS 110(1): 354-359

February – Pathfinding connections in the brain

This year there has been a burst of activity in the ‘connectomics’ field. Mapping the connections of the brain is the next big challenge of neuroscience and the main topic of the Human Brain Project in Europe and the BRAIN initiative in the US.

Here, researchers from the École Normale Supérieure in Paris, France looked at how neurons find their way from the thalamus in the middle of the brain to the outermost folds of the cortex. 

These figures show neurons in green making their way from the thalamus (Th) to the cortex (NCx). From: Deck et al. Neuron 77: 472-484.
These figures show neurons in green making their way from the thalamus (Th) to the cortex (NCx). From: Deck et al. Neuron 77: 472-484.

 

March – Whole brain activity

Seemingly a burning campfire, this is actually a brain flashing with activity. In one of the most impressive images of neuroscience in 2013, researchers from Howard Hughes Medical Institute’s Janelia Farm campus in the US used calcium imaging (see July) to view the activity of a whole brain.

The brain of a zebrafish larvae – imaged by light-sheet microscopy. From Ahrens et al. Nature Methods 10: 413-420.
The brain of a zebrafish larvae – imaged by light-sheet microscopy. From Ahrens et al. Nature Methods 10: 413-420.

One of the biggest challenges of neuroscience is working out how everything links up together. The most accurate measurements we currently have can only take into account a handful of cells at once. The brilliance of this technique, utilising see-through zebrafish larvae, is that they were able to image more than 80% of the neurons of the brain at once. This can tell you how large populations of cells interact, allowing different regions to work together.

For more info see this article by Mo Costandi in the Guardian.

 

April – See-through brains

Another amazing technical feat designed to view how the brain links together, in April we were brought CLARITY. By dissolving the opaque fat of a brain whilst keeping the structure intact, researchers led by Karl Deisseroth at Stanford University, California were able to image a whole mouse brain.

The hippocampus of a mouse, visualised with CLARITY. Excitatory cells are green, inhibitory cells are red, and support cells called astrocytes are blue. From Chung et al. Nature 497: 332-337.
The hippocampus of a mouse, visualised with CLARITY. Excitatory cells are green, inhibitory cells are red, and support cells called astrocytes are blue. From Chung et al. Nature 497: 332-337.

The images from this technique are truly breath-taking. Using this technology, researchers could look in detail at the structure of the brain, giving valuable information of the wiring of different regions. They even imaged part of a post-mortem human brain from an autistic patient, finding evidence of structural defects normally associated with Down’s syndrome.

For more info, see this article in New Scientist.

 

May – Brainbow 3.0

‘Brainbow’ is a transgenic system designed to label different types of cells in many different colours. Prime material for pretty pictures. Take a look at these:

Multicoloured neurons. b shows the hippocampus, c and d show the cortex. From: Cai et al. Nature Methods 10: 540-547
Multicoloured neurons. b shows the hippocampus, c and d show the cortex. From: Cai et al. Nature Methods 10: 540-547.

 

June – Controlling a helicopter with your mind

In June, researchers from the University of Minnesota, USA showed that one could fly a helicopter with their mind! Watch below as the subject guides a helicopter using an EEG skullcap.

July – Better calcium sensors

More calcium imaging now. Calcium imaging works by engineering chemicals that will fluoresce when they encounter calcium. When nerve cells are active, millions of calcium ions flow into the cell at once, therefore a flash of fluorescent light can be seen. Here, researchers from Howard Hughes Medical Institute’s Janelia Farm campus in the US have been working on better, more sensitive calcium sensors. Using these you can colour code neurons based on what they respond to.

Caption: Neurons colour-coded by their response properties. From Chen et al. Nature 499: 295-300.
Neurons colour-coded by their response properties. From Chen et al. Nature 499: 295-300.

They were also able to record a video of the electrical activity in dendritic spines, the tiny arborisations of nerve cells – see here.

 

August – Using electron microscopy to connect the brain

Drosophila are wonderful little flies with nervous systems simple enough to get your head around, but complicated enough to be applicable to our own.

Caption: An electron micrograph, colour coded for each individual neuron. From: Takemura et al. Nature 500: 175-181.
An electron micrograph, colour coded for each individual neuron. From: Takemura et al. Nature 500: 175-181.

Here, researchers from Janelia Farm (again!) have performed electron microscopy on drosophila brains to connect up neurons across multiple sections. An algorithm colour codes them to line up the same neuron in different sections in what looks like a work by Picasso.

 

September – Astrocytes to the rescue

Astrocytes are support cells in the brain which become highly active following brain injury. Here, researchers from Instituto Cajal, CSIC in Madrid, Spain were interested in the different characteristics astrocytes take on when a brain is injured. The injury site can be seen as a dark sphere. Astrocytes with different characteristics have been stained in different colours. For example, the turquoise-coloured astrocytes can be seen forming a protective net around the injury site.

The injury site (dark sphere) can be seen surrounded by multi-coloured astrocytes. From: Martín-López et al. PLoS ONE 8(9) .
The injury site (dark sphere) can be seen surrounded by multi-coloured astrocytes. From: Martín-López et al. PLoS ONE 8(9) .

 

October – Preserved human skulls

Not strictly neuroscience but these images need to be included. Published in October 2013, The New Cruelty (commissioned by True Entertainment), photographed a series of preserved human skulls.

A preserved human skull. From the New Cruelty exhibition, commissioned by True Entertainment.
A preserved human skull. From the New Cruelty exhibition, commissioned by True Entertainment.

 

November – Brain Computing

Part of the vision of the Human Brain Project and the BRAIN initiative is to marry anatomy of the brain with computer models to try to produce a working computer model of the brain. This image represents BrainCAT, a software designed to integrate information from different types of brain scan to gain added information about the functionality of the brain.

This image shows BrainCAT  linking functional MRI data with connectivity data (diffusion tensor imaging). From: Marques et al. Front. Hum. Neurosci. 7: 794
This image shows BrainCAT linking functional MRI data (blue and turquoise shapes) with connectivity data (diffusion tensor imaging – green lines). From: Marques et al. Front. Hum. Neurosci. 7: 794.

 

December – Men Are from Mars, Women Are from Venus.

The last month of the year gave us preposterous headlines of ‘proof’ that “Men and women’s brains are ‘wired differently’”. This finally proved why women are from Venus and men are from Mars; why men ‘are better at map reading’ and women are more ‘emotionally intelligent’…. These exaggerated headlines have been kept in check recently on this blog but there’s no denying that the research paper did show some lovely images of male and female brain connections.

The top shows the most interconnected male regions, the bottom shows the most interconnected female regions. From: Ingalhalikar et al. PNAS (online publication before print).
The top shows the most interconnected male regions, the bottom shows the most interconnected female regions. From: Ingalhalikar et al. PNAS (online publication before print).

So that’s it. 2013 was a year of flashing brains, dodgy connections and overegged hype. Let’s hope there’s even more to come in 2014.

Post by Oliver Freeman @ojfreeman

2 thoughts on “Flashes of brilliance in the brain – the best neuroscience images of 2013”

  1. I think the full animation of a simulated C. Elegans by the OpenWorm team, only done in the last month or so, deserves a mention alongside the brain computing section. It’s not every day a fully open-source science project simulating the entire nervous system of a hermaphrodite nematode gets a step closer to linking that with the muscle and hydrodynamic activity of the organism’s body.

  2. At the risk of wading into a quagmire, it’s hard to take the December study’s findings seriously, that there are new and significant hardwired differences in human male and female brains in additional to what we already knew, because the authors do not explain all the factors involved in why they found what they did.

    For example, can we raise kids in our culture along typical gender roles and biases, then at ages 12-14, say that the differences in their brains are solely due to their genders?

    To do so would be to ignore what is known about epigenetic and environmental influences in shaping the brain.

    http://surfaceyourrealself.com/2015/02/15/problematic-research-on-hardwired-differences-in-human-male-and-female-brains-surfaceyourrealself/

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